Deaerator shaft with attachment surfaces

ABSTRACT

A deaerator shaft may have a tubular intake segment that forms an intake end of the deaerator shaft, a tubular sleeve attachment segment that is adjacent to the intake segment, a tubular central segment that is adjacent to the sleeve attachment segment, the central segment having a third diameter that is greater than the second diameter, the central segment comprising a protruding ring that radially extends from the central segment and divides the central segment, the protruding ring having opposing flat surfaces, and a tubular discharge segment that forms a discharge end of the deaerator shaft. A gear may have a central ring positioned along an axis, opposing tabs that extend from a first axial side of the central ring, and a shouldered ring that extends from a second axial side of the central ring, the shouldered ring having a lip that extends radially inward toward the axis.

FIELD OF THE INVENTION

The subject matter disclosed herein relates to aircraft power systems,and in particular to a deaerator shaft and gear for use within an IDG.

BACKGROUND

in a conventional integrated drive generator (IDG) system, an inputshaft connectable to a gearbox driven by an aircraft engine is connectedto a mechanical differential, the differential having an outputconnected to drive a generator. A variable speed transmission, such as ahydromechanical transmission, is associated with the mechanicaldifferential and controlled to modify the output of the differential, asrequired, whereby the input speed to the generator remains constant eventhough the speed of the input shaft may vary.

Such systems require oil and, accordingly, IDG's may include a deaeratorsystem to separate oil from an air/oil mixture. Deaerator systems mayinclude a centrifuge device mounted to a rotating shaft that separatesthe oil from the air/oil mixture. The centrifuge mounted to a shaft willmake up the deaerator. In addition, the deaerator could be used to mountother rotating components such as a gear or Permanent Magnet Generator(PMG).

BRIEF DESCRIPTION OF THE INVENTION

In one aspect, a deaerator shaft has a plurality of segments of varyingdiameter. The plurality of segments may include a tubular intakesegment, a tubular sleeve attachment segment, a tubular central segmentand a tubular discharge segment. The intake segment forms an intake endof the deaerator shaft, the intake segment is configured to receivefluid, the intake segment having a first diameter. A tubular sleeveattachment segment is adjacent to the intake segment, the sleeveattachment segment may have a second diameter that is greater than thefirst diameter. A tubular central segment is adjacent to the sleeveattachment segment, the central segment having a third diameter that isgreater than the second diameter, the central segment comprising aprotruding ring that radially extends from the central segment anddivides the central segment, the protruding ring having opposing flatsurfaces. A tubular discharge segment that forms a discharge end of thedeaerator shaft, the tubular discharge segment is adjacent to thecentral segment, the discharge segment having a fourth diameter that isequal to the first diameter.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the invention is particularlypointed out and distinctly claimed in the claims at the conclusion ofthe specification. The foregoing and other features, and advantages ofthe invention are apparent from the following detailed description takenin conjunction with the accompanying drawings in which:

FIG. 1 is an illustration of an deaerator assembly and a pump assemblywithin a housing of an IDG in accordance with one embodiment of theinvention.

FIG. 2 is an illustration of an deaerator shaft in accordance with oneembodiment of the invention.

FIG. 3 is an illustration of an intake end of the deaerator shaft inaccordance with one embodiment of the invention.

FIG. 4 is an illustration of a discharge end of the deaerator shaft inaccordance with one embodiment of the invention.

FIG. 5 illustrates a cross-sectional view of a central segment of thedeaerator shaft in accordance with one embodiment of the invention.

FIG. 6 illustrates a cross-sectional view of a tubular dischargesegment.

FIG. 7 is an isometric view of a gear with opposing tabs in accordancewith a second embodiment of the invention.

FIG. 8 illustrates a cross-sectional view of the gear in accordance withthe second embodiment of the invention.

FIG. 9 illustrates an axial view of the gear in accordance with thesecond embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a view of a deaerator shaft 102 and pump assembly 104within an integrated drive generator (IDG) housing 106 in accordancewith one embodiment of the invention. The IDG may include the deaeratorshaft 102, a deaerator drive gear 108, the pump assembly 104, and pumpdrive gear 109. In operation, the pump assembly 104 is driven the pumpdrive gear 109. The pump drive gear 109 may be mated with a deaeratordrive gear 108 surrounding the deaerator shaft 102. As the pump drivegear 109 turns, the deaerator shaft 102 may rotate. Fluid flowing intothe deaerator shaft 102 may be centrifuged, causing a supply of oil tobe transferred and siphoned by the pump assembly 104. In operation, asufficient amount of oil is processed and flows through the deaeratorshaft 102 so that the pump assembly 104 (in particular a charge pumpcomponent of the pump assembly) may be provided with a full supply ofoil. A sufficient amount of oil may be supplied to components of the IDGfor cooling and lubrication purposes by the charge pump component.

FIG. 2 illustrates the deaerator shaft 102 in more detail. The deaeratorshaft 102 comprises a plurality of tubular segments that may extendaxially along an axis 202. The axis 202 may extend the length of thedeaerator shaft 102.

A tubular intake segment 204 is disposed along the axis 202, forming anintake end 206 of the deaerator shaft 102. The tubular intake segment204 is configured to receive fluid and has a diameter of approximately1.175 in. (2.9845 cm). The tubular intake segment 204 has a length ofapproximately 0.684 in. (1.737 cm) extending along the axis 202. The endof the tubular intake segment 206 that forms the intake end 206 ischamfered in one embodiment. The chamfered edge can form a 45 degreeangle with respect to an outer wall of the tubular intake segment 204.

The deaerator shaft 102 further comprises a tubular sleeve attachmentsegment 208 that is adjacent to the tubular intake segment 204. Thetubular sleeve attachment segment 208 extends along the axis 202 and hasa diameter that is greater than the diameter of the tubular intakesegment. In one embodiment, the diameter of the tubular sleeveattachment segment 208 is approximately 1.195 in. (3.0353 cm). Thetubular sleeve attachment segment 208 has a length of approximately0.684 in. (1.737 cm) extending along the axis 202.

The deaerator shaft 102 further comprises a central segment 210extending along the axis 202. The central segment 210 may be adjacent tothe tubular sleeve attachment segment 208, and located on an oppositeside of the tubular sleeve attachment segment 208 from the tubularintake segment 204. A protruding ring 212 extends radially from thecentral segment 210 about a circumference of the central segment 210.The protruding ring 212 divides the central segment 210, forming ashortened central segment portion 214 and a lengthened central segmentportion 215. The protruding ring 212 may have opposing flat surfaces 216on an outer radial surface of the protruding ring 212.

In one embodiment, the shortened central segment portion 214 andlengthened central segment portion 215 measure 0.347 in. (0.881 cm) and0.69 in. (1.75 cm) along the axis 202, respectively. The diameters ofthe shortened central segment portion 214 and the diameter of thelengthened central segment portion 215 may be 1.3215 in. (3.355 cm). Theprotruding ring 212 may measure 0.584 in. (1.483 cm) along the axis 202in one embodiment.

The deaerator shaft 102 may further comprise a tubular discharge segment218 extending along the axis 202, forming a discharge end 219 of thedeaerator shaft 102. The tubular discharge segment 218 may be adjacentto the shortened central segment portion 214. The tubular dischargesegment 218 has a diameter of approximately 1.175 in. (2.984 cm), whichis approximately equal to the diameter of the tubular intake segment204.

The tubular discharge segment 218 may comprise a plurality of openings220. The plurality of openings 220 is disposed about a circumference ofthe tubular discharge segment 218. The plurality of openings 220 may bespaced equally around a circumference of the tubular discharge segment218. Each opening extends in an axial direction for approximately 0.88in. (2.2352 cm) along the axis 202. As described in more detail below,the plurality of openings 220 can act as a primary discharge point forfluid flowing through the deaerator shaft 102. The discharge end 219 mayact as a secondary discharge point for fluid, and the tubular dischargesegment 218 may be chamfered at the discharge end 218.

FIGS. 3 and 4 illustrate a rotated view of the deaerator shaft 102. Aplurality of vanes 302 may extend from a radial center of the deaeratorshaft 102 to an interior wall 303 of the deaerator shaft 102. Theplurality of vanes 302 may extend axially along a length of thedeaerator shaft 102, forming channels within the interior of thedeaerator shaft 102. The channels may assist with accelerating the fluidfrom longitudinal flow to rotating flow as the deaerator shaft 102rotates, and as the fluid travels from the intake end 206 to thedischarge end 219. Each channel may terminate at a respective opening ofthe plurality of openings 220. In one embodiment, three vanes extendfrom a radial center of the deaerator shaft 102, forming three channelsof equal capacity. Each vane terminates at the inner wall at a point 120degrees apart from an adjacent vane.

The plurality of vanes 302 may be axially recessed within the tubularintake segment 206 and the tubular discharge segment 219. Accordingly,the plurality of vanes 302 may not extend the entire length of thedeaerator shaft 102. As shown in FIG. 3, the intake edges 304 of theplurality of vanes 302 are recessed with respect to the intake end 206of the deaerator shaft 102. The distance from the intake edges 304 ofthe plurality of vanes 302 to the intake end 206 may be 0.125 in. (0.318cm), in one embodiment.

In FIG. 4, the plurality of vanes 302 are axially recessed relative tothe discharge end 219 of the deaerator shaft 102. In particular,discharge edges 402 of the plurality of vanes 302 are recessed withrespect to the discharge end 219 of the deaerator shaft 102. The lengthof the recess between the discharge end 219 and the discharge edges 402can vary, but in one embodiment the length of the recess is 0.376 in.(0.955 cm). Furthermore, the discharge edges 402 may be cupped, with acentral part of the plurality of vanes 302 further recessed with respectto the discharge edges 402.

FIG. 5 illustrates a cross-sectional view of the central segment 212.Each vane of the plurality of vanes 302 may form a rounded surface 502with the inner radial wall of the central segment 212. The roundedsurface 502 may promote ease of manufacture of the vanes. The diameterof the protruding ring 212 as measured between outer radial walls of theprotruding ring 212 may be 1.562 in. (3.967 cm) in one embodiment. Thedistance between opposing flat surfaces 504, 506 of the protruding ring212 may be approximately 1.374 in. (3.48 cm). The opposing flat surfaces504, 506 may run parallel to one another.

FIG. 6 illustrates a cross-sectional view of the tubular dischargesegment 218. The configuration of the plurality of vanes 302 extendingthrough the tubular discharge segment 218 is illustrated in more detail.In particular, the plurality of vanes 302 is cupped, forming a centraldischarge opening 602 between fins 604 of the plurality of vanes 302.The central discharge opening 602 may extend 1.183 in. (3.005 cm) fromthe discharge end 219, and radially 0.4 in. (1.016 cm). The plurality ofvanes 302 may be recessed 0.376 in. (0.955 cm) from the discharge end.Accordingly, each fin 604 of the plurality of vanes 302 may extend 0.807in. (2.05 cm) along the axis 202. Although an edge 606 of the fin 604 issquared in FIG. 6, the edge 606 of each fin 604 may have a rounded edge.

Referring to FIG. 7 with continuing reference to FIGS. 2 and 5, anisometric view of a gear 700 is shown in accordance with the subjectinvention. The gear 700 is ring-shaped with opposing tabs 702, 704 thatextend axially from an inner side 706 of the gear 700. As described inmore detail below, the opposing tabs 702, 704 are configured to lockwith the opposing flat surfaces (not shown) of the protruding ring (notshown). The opposing tabs 702, 704 are used to provide a positivetransfer of torque from the gear 700 to the deaerator shaft. The gear700 is axially mounted on protruding ring 212. The opposing tabs 702,704 drive on opposing flat surfaces 504, 506 of the deaerator shaft,transmitting torque to the deaerator shaft.

FIG. 8 illustrates a cross-sectional view of the gear 700. The gear 700is disposed along an axis 802. The gear 700 has a central ring 804 witha diameter of approximately 1.3254 in. (3.366 cm) between inner radialwalls of the central ring 804. The gear 700 has a plurality of teeth 806circumferentially disposed about an outer radial surface of the centralring 804. The plurality of teeth 806 extend along the axial length ofthe central ring 804. The plurality of teeth 806 provide a thrustsurface by which a mating gear (not shown) may transmit torque to gear700. In one embodiment, the central ring 804 and the plurality of teeth806 have an axial length of 0.35 in. (0.889 cm).

The gear 700 has a shouldered ring 808 with a diameter between innerradial surface 810 of the shouldered ring 808 of 1.195 in. (3.035 cm),and a diameter between outer radial surface 814 of the shouldered ring808 of 1.513 in. (3.843 cm). The shouldered ring 808 may extend axiallyfrom the central ring 804 for a distance of 0.84 in. (2.133 cm). Theshouldered ring 808 also provides a thrust surface when mounted to thedeaerator shaft and helps to axially locate the deaerator shaft withinthe IDG.

The opposing tabs 702, 704 of gear 700 extend in a direction opposite tothe shouldered ring 808. The opposing tabs 702, 704 may extend 0.2 in.(0.508 cm) in an axial direction.

FIG. 9 illustrates an axial view of the gear 700. The opposing tabs 702,704 have a length of 0.35 in. (0.889 cm) extending along thecross-sectional axis 802. Radially-inward facing surfaces 806, 807 ofthe opposing tabs 702, 704 are flat. However, the radially-outwardfacing surfaces 808, 810 of the opposing tabs 702, 704 may be arced,similar to the circumference of the central ring 804.

While the invention has been described in detail in connection with onlya limited number of embodiments, it should be readily understood thatthe invention is not limited to such disclosed embodiments. Rather, theinvention can be modified to incorporate any number of variations,alterations, substitutions or equivalent arrangements not heretoforedescribed, but which are commensurate with the spirit and scope of theinvention. Additionally, while various embodiments of the invention havebeen described, it is to be understood that aspects of the invention mayinclude only some of the described embodiments. Accordingly, theinvention is not to be seen as limited by the foregoing description, butis only limited by the scope of the appended claims.

The invention claimed is:
 1. A deaerator shaft comprising: a tubularintake segment that forms an intake end of the deaerator shaft, thetubular intake segment is configured to receive fluid, the intakesegment having a first diameter; a tubular sleeve attachment segmentthat is adjacent to the intake segment, the tubular sleeve attachmentsegment having a second diameter that is greater than the firstdiameter; a tubular central segment that is adjacent to the sleeveattachment segment, the tubular central segment having a third diameterthat is greater than the second diameter, the tubular central segmentcomprising a protruding ring that radially extends from the tubularcentral segment and divides the tubular central segment, the protrudingring having opposing flat surfaces and further comprising a plurality ofvanes, wherein each of the plurality of vanes form a rounded surfacewith an inner radial wall of the central segment; and a tubulardischarge segment that forms a discharge end of the deaerator shaftcomprising a plurality of openings circumferentially disposed about acircumference of the tubular discharge segment, wherein the tubulardischarge segment is adjacent to the central segment, the tubulardischarge segment having a fourth diameter that is approximately equalto the first diameter.
 2. The deaerator shaft of claim 1, wherein atleast one corner of the plurality of openings are rounded.
 3. Thedeaerator shaft of claim 1, wherein the plurality of vanes extend from aradial center of the deaerator shaft to the interior radial wall of thedeaerator shaft.
 4. The deaerator shaft of claim 3, wherein theplurality of vanes form the rounded surface with the inner radial wallof the central segment and are axially recessed within the tubularintake segment.
 5. The deaerator shaft of claim 4, wherein the pluralityof vanes are recessed within the tubular intake segment and the tubulardischarge segment.
 6. The deaerator shaft of claim 5, wherein theplurality of vanes extend axially between the plurality of openings. 7.The deaerator shaft of claim 6, wherein a central divider of theplurality of vanes is removed within the tubular discharge segment. 8.The deaerator shaft of claim 1, wherein the tubular intake segment has adiameter of approximately 1.175 in. (2.9845 cm).
 9. The deaerator shaftof claim 1, wherein the protruding ring axially extends approximately0.584 in. (1.483 cm).